/*- * Copyright (c) 2009, 2013 The FreeBSD Foundation * All rights reserved. * * This software was developed by Ed Schouten under sponsorship from the * FreeBSD Foundation. * * Portions of this software were developed by Oleksandr Rybalko * under sponsorship from the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include "opt_compat.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if defined(__i386__) || defined(__amd64__) #include #include #endif static tc_bell_t vtterm_bell; static tc_cursor_t vtterm_cursor; static tc_putchar_t vtterm_putchar; static tc_fill_t vtterm_fill; static tc_copy_t vtterm_copy; static tc_param_t vtterm_param; static tc_done_t vtterm_done; static tc_cnprobe_t vtterm_cnprobe; static tc_cngetc_t vtterm_cngetc; static tc_cngrab_t vtterm_cngrab; static tc_cnungrab_t vtterm_cnungrab; static tc_opened_t vtterm_opened; static tc_ioctl_t vtterm_ioctl; static tc_mmap_t vtterm_mmap; const struct terminal_class vt_termclass = { .tc_bell = vtterm_bell, .tc_cursor = vtterm_cursor, .tc_putchar = vtterm_putchar, .tc_fill = vtterm_fill, .tc_copy = vtterm_copy, .tc_param = vtterm_param, .tc_done = vtterm_done, .tc_cnprobe = vtterm_cnprobe, .tc_cngetc = vtterm_cngetc, .tc_cngrab = vtterm_cngrab, .tc_cnungrab = vtterm_cnungrab, .tc_opened = vtterm_opened, .tc_ioctl = vtterm_ioctl, .tc_mmap = vtterm_mmap, }; /* * Use a constant timer of 25 Hz to redraw the screen. * * XXX: In theory we should only fire up the timer when there is really * activity. Unfortunately we cannot always start timers. We really * don't want to process kernel messages synchronously, because it * really slows down the system. */ #define VT_TIMERFREQ 25 /* Bell pitch/duration. */ #define VT_BELLDURATION ((5 * hz + 99) / 100) #define VT_BELLPITCH 800 #define VT_UNIT(vw) ((vw)->vw_device->vd_unit * VT_MAXWINDOWS + \ (vw)->vw_number) static SYSCTL_NODE(_kern, OID_AUTO, vt, CTLFLAG_RD, 0, "vt(9) parameters"); static VT_SYSCTL_INT(enable_altgr, 1, "Enable AltGr key (Do not assume R.Alt as Alt)"); static VT_SYSCTL_INT(enable_bell, 1, "Enable bell"); static VT_SYSCTL_INT(debug, 0, "vt(9) debug level"); static VT_SYSCTL_INT(deadtimer, 15, "Time to wait busy process in VT_PROCESS mode"); static VT_SYSCTL_INT(suspendswitch, 1, "Switch to VT0 before suspend"); /* Allow to disable some keyboard combinations. */ static VT_SYSCTL_INT(kbd_halt, 1, "Enable halt keyboard combination. " "See kbdmap(5) to configure."); static VT_SYSCTL_INT(kbd_poweroff, 1, "Enable Power Off keyboard combination. " "See kbdmap(5) to configure."); static VT_SYSCTL_INT(kbd_reboot, 1, "Enable reboot keyboard combination. " "See kbdmap(5) to configure (typically Ctrl-Alt-Delete)."); static VT_SYSCTL_INT(kbd_debug, 1, "Enable key combination to enter debugger. " "See kbdmap(5) to configure (typically Ctrl-Alt-Esc)."); static VT_SYSCTL_INT(kbd_panic, 0, "Enable request to panic. " "See kbdmap(5) to configure."); /* Used internally, not a tunable. */ int vt_draw_logo_cpus; VT_SYSCTL_INT(splash_cpu, 0, "Show logo CPUs during boot"); VT_SYSCTL_INT(splash_ncpu, 0, "Override number of logos displayed " "(0 = do not override)"); VT_SYSCTL_INT(splash_cpu_style, 2, "Draw logo style " "(0 = Alternate beastie, 1 = Beastie, 2 = Orb)"); VT_SYSCTL_INT(splash_cpu_duration, 10, "Hide logos after (seconds)"); static struct vt_device vt_consdev; static unsigned int vt_unit = 0; static MALLOC_DEFINE(M_VT, "vt", "vt device"); struct vt_device *main_vd = &vt_consdev; /* Boot logo. */ extern unsigned int vt_logo_width; extern unsigned int vt_logo_height; extern unsigned int vt_logo_depth; extern unsigned char vt_logo_image[]; #ifndef DEV_SPLASH #define vtterm_draw_cpu_logos(...) do {} while (0) const unsigned int vt_logo_sprite_height; #endif /* Font. */ extern struct vt_font vt_font_default; #ifndef SC_NO_CUTPASTE extern struct vt_mouse_cursor vt_default_mouse_pointer; #endif static int signal_vt_rel(struct vt_window *); static int signal_vt_acq(struct vt_window *); static int finish_vt_rel(struct vt_window *, int, int *); static int finish_vt_acq(struct vt_window *); static int vt_window_switch(struct vt_window *); static int vt_late_window_switch(struct vt_window *); static int vt_proc_alive(struct vt_window *); static void vt_resize(struct vt_device *); static void vt_update_static(void *); #ifndef SC_NO_CUTPASTE static void vt_mouse_paste(void); #endif static void vt_suspend_handler(void *priv); static void vt_resume_handler(void *priv); SET_DECLARE(vt_drv_set, struct vt_driver); #define _VTDEFH MAX(100, PIXEL_HEIGHT(VT_FB_DEFAULT_HEIGHT)) #define _VTDEFW MAX(200, PIXEL_WIDTH(VT_FB_DEFAULT_WIDTH)) struct terminal vt_consterm; static struct vt_window vt_conswindow; static struct vt_device vt_consdev = { .vd_driver = NULL, .vd_softc = NULL, .vd_prev_driver = NULL, .vd_prev_softc = NULL, .vd_flags = VDF_INVALID, .vd_windows = { [VT_CONSWINDOW] = &vt_conswindow, }, .vd_curwindow = &vt_conswindow, .vd_kbstate = 0, #ifndef SC_NO_CUTPASTE .vd_pastebuf = { .vpb_buf = NULL, .vpb_bufsz = 0, .vpb_len = 0 }, .vd_mcursor = &vt_default_mouse_pointer, .vd_mcursor_fg = TC_WHITE, .vd_mcursor_bg = TC_BLACK, #endif }; static term_char_t vt_constextbuf[(_VTDEFW) * (VBF_DEFAULT_HISTORY_SIZE)]; static term_char_t *vt_constextbufrows[VBF_DEFAULT_HISTORY_SIZE]; static struct vt_window vt_conswindow = { .vw_number = VT_CONSWINDOW, .vw_flags = VWF_CONSOLE, .vw_buf = { .vb_buffer = &vt_constextbuf[0], .vb_rows = &vt_constextbufrows[0], .vb_history_size = VBF_DEFAULT_HISTORY_SIZE, .vb_curroffset = 0, .vb_roffset = 0, .vb_flags = VBF_STATIC, .vb_mark_start = {.tp_row = 0, .tp_col = 0,}, .vb_mark_end = {.tp_row = 0, .tp_col = 0,}, .vb_scr_size = { .tp_row = _VTDEFH, .tp_col = _VTDEFW, }, }, .vw_device = &vt_consdev, .vw_terminal = &vt_consterm, .vw_kbdmode = K_XLATE, .vw_grabbed = 0, }; struct terminal vt_consterm = { .tm_class = &vt_termclass, .tm_softc = &vt_conswindow, .tm_flags = TF_CONS, }; static struct consdev vt_consterm_consdev = { .cn_ops = &termcn_cnops, .cn_arg = &vt_consterm, .cn_name = "ttyv0", }; /* Add to set of consoles. */ DATA_SET(cons_set, vt_consterm_consdev); /* * Right after kmem is done to allow early drivers to use locking and allocate * memory. */ SYSINIT(vt_update_static, SI_SUB_KMEM, SI_ORDER_ANY, vt_update_static, &vt_consdev); /* Delay until all devices attached, to not waste time. */ SYSINIT(vt_early_cons, SI_SUB_INT_CONFIG_HOOKS, SI_ORDER_ANY, vt_upgrade, &vt_consdev); /* Initialize locks/mem depended members. */ static void vt_update_static(void *dummy) { if (!vty_enabled(VTY_VT)) return; if (main_vd->vd_driver != NULL) printf("VT: running with driver \"%s\".\n", main_vd->vd_driver->vd_name); else printf("VT: init without driver.\n"); mtx_init(&main_vd->vd_lock, "vtdev", NULL, MTX_DEF); cv_init(&main_vd->vd_winswitch, "vtwswt"); } static void vt_schedule_flush(struct vt_device *vd, int ms) { if (ms <= 0) /* Default to initial value. */ ms = 1000 / VT_TIMERFREQ; callout_schedule(&vd->vd_timer, hz / (1000 / ms)); } void vt_resume_flush_timer(struct vt_device *vd, int ms) { if (!(vd->vd_flags & VDF_ASYNC) || !atomic_cmpset_int(&vd->vd_timer_armed, 0, 1)) return; vt_schedule_flush(vd, ms); } static void vt_suspend_flush_timer(struct vt_device *vd) { /* * As long as this function is called locked, callout_stop() * has the same effect like callout_drain() with regard to * preventing the callback function from executing. */ VT_LOCK_ASSERT(vd, MA_OWNED); if (!(vd->vd_flags & VDF_ASYNC) || !atomic_cmpset_int(&vd->vd_timer_armed, 1, 0)) return; callout_stop(&vd->vd_timer); } static void vt_switch_timer(void *arg) { vt_late_window_switch((struct vt_window *)arg); } static int vt_save_kbd_mode(struct vt_window *vw, keyboard_t *kbd) { int mode, ret; mode = 0; ret = kbdd_ioctl(kbd, KDGKBMODE, (caddr_t)&mode); if (ret == ENOIOCTL) ret = ENODEV; if (ret != 0) return (ret); vw->vw_kbdmode = mode; return (0); } static int vt_update_kbd_mode(struct vt_window *vw, keyboard_t *kbd) { int ret; ret = kbdd_ioctl(kbd, KDSKBMODE, (caddr_t)&vw->vw_kbdmode); if (ret == ENOIOCTL) ret = ENODEV; return (ret); } static int vt_save_kbd_state(struct vt_window *vw, keyboard_t *kbd) { int state, ret; state = 0; ret = kbdd_ioctl(kbd, KDGKBSTATE, (caddr_t)&state); if (ret == ENOIOCTL) ret = ENODEV; if (ret != 0) return (ret); vw->vw_kbdstate &= ~LOCK_MASK; vw->vw_kbdstate |= state & LOCK_MASK; return (0); } static int vt_update_kbd_state(struct vt_window *vw, keyboard_t *kbd) { int state, ret; state = vw->vw_kbdstate & LOCK_MASK; ret = kbdd_ioctl(kbd, KDSKBSTATE, (caddr_t)&state); if (ret == ENOIOCTL) ret = ENODEV; return (ret); } static int vt_save_kbd_leds(struct vt_window *vw, keyboard_t *kbd) { int leds, ret; leds = 0; ret = kbdd_ioctl(kbd, KDGETLED, (caddr_t)&leds); if (ret == ENOIOCTL) ret = ENODEV; if (ret != 0) return (ret); vw->vw_kbdstate &= ~LED_MASK; vw->vw_kbdstate |= leds & LED_MASK; return (0); } static int vt_update_kbd_leds(struct vt_window *vw, keyboard_t *kbd) { int leds, ret; leds = vw->vw_kbdstate & LED_MASK; ret = kbdd_ioctl(kbd, KDSETLED, (caddr_t)&leds); if (ret == ENOIOCTL) ret = ENODEV; return (ret); } static int vt_window_preswitch(struct vt_window *vw, struct vt_window *curvw) { DPRINTF(40, "%s\n", __func__); curvw->vw_switch_to = vw; /* Set timer to allow switch in case when process hang. */ callout_reset(&vw->vw_proc_dead_timer, hz * vt_deadtimer, vt_switch_timer, (void *)vw); /* Notify process about vt switch attempt. */ DPRINTF(30, "%s: Notify process.\n", __func__); signal_vt_rel(curvw); return (0); } static int vt_window_postswitch(struct vt_window *vw) { signal_vt_acq(vw); return (0); } /* vt_late_window_switch will done VT switching for regular case. */ static int vt_late_window_switch(struct vt_window *vw) { int ret; callout_stop(&vw->vw_proc_dead_timer); ret = vt_window_switch(vw); if (ret) return (ret); /* Notify owner process about terminal availability. */ if (vw->vw_smode.mode == VT_PROCESS) { ret = vt_window_postswitch(vw); } return (ret); } /* Switch window. */ static int vt_proc_window_switch(struct vt_window *vw) { struct vt_window *curvw; struct vt_device *vd; int ret; /* Prevent switching to NULL */ if (vw == NULL) { DPRINTF(30, "%s: Cannot switch: vw is NULL.", __func__); return (EINVAL); } vd = vw->vw_device; curvw = vd->vd_curwindow; /* Check if virtual terminal is locked */ if (curvw->vw_flags & VWF_VTYLOCK) return (EBUSY); /* Check if switch already in progress */ if (curvw->vw_flags & VWF_SWWAIT_REL) { /* Check if switching to same window */ if (curvw->vw_switch_to == vw) { DPRINTF(30, "%s: Switch in progress to same vw.", __func__); return (0); /* success */ } DPRINTF(30, "%s: Switch in progress to different vw.", __func__); return (EBUSY); } /* Avoid switching to already selected window */ if (vw == curvw) { DPRINTF(30, "%s: Cannot switch: vw == curvw.", __func__); return (0); /* success */ } /* Ask current process permission to switch away. */ if (curvw->vw_smode.mode == VT_PROCESS) { DPRINTF(30, "%s: VT_PROCESS ", __func__); if (vt_proc_alive(curvw) == FALSE) { DPRINTF(30, "Dead. Cleaning."); /* Dead */ } else { DPRINTF(30, "%s: Signaling process.\n", __func__); /* Alive, try to ask him. */ ret = vt_window_preswitch(vw, curvw); /* Wait for process answer or timeout. */ return (ret); } DPRINTF(30, "\n"); } ret = vt_late_window_switch(vw); return (ret); } /* Switch window ignoring process locking. */ static int vt_window_switch(struct vt_window *vw) { struct vt_device *vd = vw->vw_device; struct vt_window *curvw = vd->vd_curwindow; keyboard_t *kbd; VT_LOCK(vd); if (curvw == vw) { /* Nothing to do. */ VT_UNLOCK(vd); return (0); } if (!(vw->vw_flags & (VWF_OPENED|VWF_CONSOLE))) { VT_UNLOCK(vd); return (EINVAL); } vt_suspend_flush_timer(vd); vd->vd_curwindow = vw; vd->vd_flags |= VDF_INVALID; cv_broadcast(&vd->vd_winswitch); VT_UNLOCK(vd); if (vd->vd_driver->vd_postswitch) vd->vd_driver->vd_postswitch(vd); vt_resume_flush_timer(vd, 0); /* Restore per-window keyboard mode. */ mtx_lock(&Giant); kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd != NULL) { if (curvw->vw_kbdmode == K_XLATE) vt_save_kbd_state(curvw, kbd); vt_update_kbd_mode(vw, kbd); vt_update_kbd_state(vw, kbd); } mtx_unlock(&Giant); DPRINTF(10, "%s(ttyv%d) done\n", __func__, vw->vw_number); return (0); } void vt_termsize(struct vt_device *vd, struct vt_font *vf, term_pos_t *size) { size->tp_row = vd->vd_height; if (vt_draw_logo_cpus) size->tp_row -= vt_logo_sprite_height; size->tp_col = vd->vd_width; if (vf != NULL) { size->tp_row /= vf->vf_height; size->tp_col /= vf->vf_width; } } static inline void vt_termrect(struct vt_device *vd, struct vt_font *vf, term_rect_t *rect) { rect->tr_begin.tp_row = rect->tr_begin.tp_col = 0; if (vt_draw_logo_cpus) rect->tr_begin.tp_row = vt_logo_sprite_height; rect->tr_end.tp_row = vd->vd_height; rect->tr_end.tp_col = vd->vd_width; if (vf != NULL) { rect->tr_begin.tp_row = howmany(rect->tr_begin.tp_row, vf->vf_height); rect->tr_end.tp_row /= vf->vf_height; rect->tr_end.tp_col /= vf->vf_width; } } void vt_winsize(struct vt_device *vd, struct vt_font *vf, struct winsize *size) { size->ws_ypixel = vd->vd_height; if (vt_draw_logo_cpus) size->ws_ypixel -= vt_logo_sprite_height; size->ws_row = size->ws_ypixel; size->ws_col = size->ws_xpixel = vd->vd_width; if (vf != NULL) { size->ws_row /= vf->vf_height; size->ws_col /= vf->vf_width; } } void vt_compute_drawable_area(struct vt_window *vw) { struct vt_device *vd; struct vt_font *vf; vt_axis_t height; vd = vw->vw_device; if (vw->vw_font == NULL) { vw->vw_draw_area.tr_begin.tp_col = 0; vw->vw_draw_area.tr_begin.tp_row = 0; if (vt_draw_logo_cpus) vw->vw_draw_area.tr_begin.tp_row = vt_logo_sprite_height; vw->vw_draw_area.tr_end.tp_col = vd->vd_width; vw->vw_draw_area.tr_end.tp_row = vd->vd_height; return; } vf = vw->vw_font; /* * Compute the drawable area, so that the text is centered on * the screen. */ height = vd->vd_height; if (vt_draw_logo_cpus) height -= vt_logo_sprite_height; vw->vw_draw_area.tr_begin.tp_col = (vd->vd_width % vf->vf_width) / 2; vw->vw_draw_area.tr_begin.tp_row = (height % vf->vf_height) / 2; if (vt_draw_logo_cpus) vw->vw_draw_area.tr_begin.tp_row += vt_logo_sprite_height; vw->vw_draw_area.tr_end.tp_col = vw->vw_draw_area.tr_begin.tp_col + vd->vd_width / vf->vf_width * vf->vf_width; vw->vw_draw_area.tr_end.tp_row = vw->vw_draw_area.tr_begin.tp_row + height / vf->vf_height * vf->vf_height; } static void vt_scroll(struct vt_window *vw, int offset, int whence) { int diff; term_pos_t size; if ((vw->vw_flags & VWF_SCROLL) == 0) return; vt_termsize(vw->vw_device, vw->vw_font, &size); diff = vthistory_seek(&vw->vw_buf, offset, whence); if (diff) vw->vw_device->vd_flags |= VDF_INVALID; vt_resume_flush_timer(vw->vw_device, 0); } static int vt_machine_kbdevent(int c) { switch (c) { case SPCLKEY | DBG: /* kbdmap(5) keyword `debug`. */ if (vt_kbd_debug) kdb_enter(KDB_WHY_BREAK, "manual escape to debugger"); return (1); case SPCLKEY | HALT: /* kbdmap(5) keyword `halt`. */ if (vt_kbd_halt) shutdown_nice(RB_HALT); return (1); case SPCLKEY | PASTE: /* kbdmap(5) keyword `paste`. */ #ifndef SC_NO_CUTPASTE /* Insert text from cut-paste buffer. */ vt_mouse_paste(); #endif break; case SPCLKEY | PDWN: /* kbdmap(5) keyword `pdwn`. */ if (vt_kbd_poweroff) shutdown_nice(RB_HALT|RB_POWEROFF); return (1); case SPCLKEY | PNC: /* kbdmap(5) keyword `panic`. */ /* * Request to immediate panic if sysctl * kern.vt.enable_panic_key allow it. */ if (vt_kbd_panic) panic("Forced by the panic key"); return (1); case SPCLKEY | RBT: /* kbdmap(5) keyword `boot`. */ if (vt_kbd_reboot) shutdown_nice(RB_AUTOBOOT); return (1); case SPCLKEY | SPSC: /* kbdmap(5) keyword `spsc`. */ /* Force activatation/deactivation of the screen saver. */ /* TODO */ return (1); case SPCLKEY | STBY: /* XXX Not present in kbdcontrol parser. */ /* Put machine into Stand-By mode. */ power_pm_suspend(POWER_SLEEP_STATE_STANDBY); return (1); case SPCLKEY | SUSP: /* kbdmap(5) keyword `susp`. */ /* Suspend machine. */ power_pm_suspend(POWER_SLEEP_STATE_SUSPEND); return (1); }; return (0); } static void vt_scrollmode_kbdevent(struct vt_window *vw, int c, int console) { struct vt_device *vd; term_pos_t size; vd = vw->vw_device; /* Only special keys handled in ScrollLock mode */ if ((c & SPCLKEY) == 0) return; c &= ~SPCLKEY; if (console == 0) { if (c >= F_SCR && c <= MIN(L_SCR, F_SCR + VT_MAXWINDOWS - 1)) { vw = vd->vd_windows[c - F_SCR]; vt_proc_window_switch(vw); return; } VT_LOCK(vd); } switch (c) { case SLK: { /* Turn scrolling off. */ vt_scroll(vw, 0, VHS_END); VTBUF_SLCK_DISABLE(&vw->vw_buf); vw->vw_flags &= ~VWF_SCROLL; break; } case FKEY | F(49): /* Home key. */ vt_scroll(vw, 0, VHS_SET); break; case FKEY | F(50): /* Arrow up. */ vt_scroll(vw, -1, VHS_CUR); break; case FKEY | F(51): /* Page up. */ vt_termsize(vd, vw->vw_font, &size); vt_scroll(vw, -size.tp_row, VHS_CUR); break; case FKEY | F(57): /* End key. */ vt_scroll(vw, 0, VHS_END); break; case FKEY | F(58): /* Arrow down. */ vt_scroll(vw, 1, VHS_CUR); break; case FKEY | F(59): /* Page down. */ vt_termsize(vd, vw->vw_font, &size); vt_scroll(vw, size.tp_row, VHS_CUR); break; } if (console == 0) VT_UNLOCK(vd); } static int vt_processkey(keyboard_t *kbd, struct vt_device *vd, int c) { struct vt_window *vw = vd->vd_curwindow; random_harvest_queue(&c, sizeof(c), 1, RANDOM_KEYBOARD); #if VT_ALT_TO_ESC_HACK if (c & RELKEY) { switch (c & ~RELKEY) { case (SPCLKEY | RALT): if (vt_enable_altgr != 0) break; case (SPCLKEY | LALT): vd->vd_kbstate &= ~ALKED; } /* Other keys ignored for RELKEY event. */ return (0); } else { switch (c & ~RELKEY) { case (SPCLKEY | RALT): if (vt_enable_altgr != 0) break; case (SPCLKEY | LALT): vd->vd_kbstate |= ALKED; } } #else if (c & RELKEY) /* Other keys ignored for RELKEY event. */ return (0); #endif if (vt_machine_kbdevent(c)) return (0); if (vw->vw_flags & VWF_SCROLL) { vt_scrollmode_kbdevent(vw, c, 0/* Not a console */); /* Scroll mode keys handled, nothing to do more. */ return (0); } if (c & SPCLKEY) { c &= ~SPCLKEY; if (c >= F_SCR && c <= MIN(L_SCR, F_SCR + VT_MAXWINDOWS - 1)) { vw = vd->vd_windows[c - F_SCR]; vt_proc_window_switch(vw); return (0); } switch (c) { case NEXT: /* Switch to next VT. */ c = (vw->vw_number + 1) % VT_MAXWINDOWS; vw = vd->vd_windows[c]; vt_proc_window_switch(vw); return (0); case PREV: /* Switch to previous VT. */ c = (vw->vw_number + VT_MAXWINDOWS - 1) % VT_MAXWINDOWS; vw = vd->vd_windows[c]; vt_proc_window_switch(vw); return (0); case SLK: { vt_save_kbd_state(vw, kbd); VT_LOCK(vd); if (vw->vw_kbdstate & SLKED) { /* Turn scrolling on. */ vw->vw_flags |= VWF_SCROLL; VTBUF_SLCK_ENABLE(&vw->vw_buf); } else { /* Turn scrolling off. */ vw->vw_flags &= ~VWF_SCROLL; VTBUF_SLCK_DISABLE(&vw->vw_buf); vt_scroll(vw, 0, VHS_END); } VT_UNLOCK(vd); break; } case FKEY | F(1): case FKEY | F(2): case FKEY | F(3): case FKEY | F(4): case FKEY | F(5): case FKEY | F(6): case FKEY | F(7): case FKEY | F(8): case FKEY | F(9): case FKEY | F(10): case FKEY | F(11): case FKEY | F(12): /* F1 through F12 keys. */ terminal_input_special(vw->vw_terminal, TKEY_F1 + c - (FKEY | F(1))); break; case FKEY | F(49): /* Home key. */ terminal_input_special(vw->vw_terminal, TKEY_HOME); break; case FKEY | F(50): /* Arrow up. */ terminal_input_special(vw->vw_terminal, TKEY_UP); break; case FKEY | F(51): /* Page up. */ terminal_input_special(vw->vw_terminal, TKEY_PAGE_UP); break; case FKEY | F(53): /* Arrow left. */ terminal_input_special(vw->vw_terminal, TKEY_LEFT); break; case FKEY | F(55): /* Arrow right. */ terminal_input_special(vw->vw_terminal, TKEY_RIGHT); break; case FKEY | F(57): /* End key. */ terminal_input_special(vw->vw_terminal, TKEY_END); break; case FKEY | F(58): /* Arrow down. */ terminal_input_special(vw->vw_terminal, TKEY_DOWN); break; case FKEY | F(59): /* Page down. */ terminal_input_special(vw->vw_terminal, TKEY_PAGE_DOWN); break; case FKEY | F(60): /* Insert key. */ terminal_input_special(vw->vw_terminal, TKEY_INSERT); break; case FKEY | F(61): /* Delete key. */ terminal_input_special(vw->vw_terminal, TKEY_DELETE); break; } } else if (KEYFLAGS(c) == 0) { /* Don't do UTF-8 conversion when doing raw mode. */ if (vw->vw_kbdmode == K_XLATE) { #if VT_ALT_TO_ESC_HACK if (vd->vd_kbstate & ALKED) { /* * Prepend ESC sequence if one of ALT keys down. */ terminal_input_char(vw->vw_terminal, 0x1b); } #endif #if defined(KDB) kdb_alt_break(c, &vd->vd_altbrk); #endif terminal_input_char(vw->vw_terminal, KEYCHAR(c)); } else terminal_input_raw(vw->vw_terminal, c); } return (0); } static int vt_kbdevent(keyboard_t *kbd, int event, void *arg) { struct vt_device *vd = arg; int c; switch (event) { case KBDIO_KEYINPUT: break; case KBDIO_UNLOADING: mtx_lock(&Giant); vd->vd_keyboard = -1; kbd_release(kbd, (void *)vd); mtx_unlock(&Giant); return (0); default: return (EINVAL); } while ((c = kbdd_read_char(kbd, 0)) != NOKEY) vt_processkey(kbd, vd, c); return (0); } static int vt_allocate_keyboard(struct vt_device *vd) { int idx0, idx; keyboard_t *k0, *k; keyboard_info_t ki; idx0 = kbd_allocate("kbdmux", -1, vd, vt_kbdevent, vd); if (idx0 >= 0) { DPRINTF(20, "%s: kbdmux allocated, idx = %d\n", __func__, idx0); k0 = kbd_get_keyboard(idx0); for (idx = kbd_find_keyboard2("*", -1, 0); idx != -1; idx = kbd_find_keyboard2("*", -1, idx + 1)) { k = kbd_get_keyboard(idx); if (idx == idx0 || KBD_IS_BUSY(k)) continue; bzero(&ki, sizeof(ki)); strncpy(ki.kb_name, k->kb_name, sizeof(ki.kb_name)); ki.kb_name[sizeof(ki.kb_name) - 1] = '\0'; ki.kb_unit = k->kb_unit; kbdd_ioctl(k0, KBADDKBD, (caddr_t) &ki); } } else { DPRINTF(20, "%s: no kbdmux allocated\n", __func__); idx0 = kbd_allocate("*", -1, vd, vt_kbdevent, vd); if (idx0 < 0) { DPRINTF(10, "%s: No keyboard found.\n", __func__); return (-1); } } vd->vd_keyboard = idx0; DPRINTF(20, "%s: vd_keyboard = %d\n", __func__, vd->vd_keyboard); return (idx0); } static void vtterm_bell(struct terminal *tm) { struct vt_window *vw = tm->tm_softc; struct vt_device *vd = vw->vw_device; if (!vt_enable_bell) return; if (vd->vd_flags & VDF_QUIET_BELL) return; sysbeep(1193182 / VT_BELLPITCH, VT_BELLDURATION); } static void vtterm_beep(struct terminal *tm, u_int param) { u_int freq, period; if (!vt_enable_bell) return; if ((param == 0) || ((param & 0xffff) == 0)) { vtterm_bell(tm); return; } period = ((param >> 16) & 0xffff) * hz / 1000; freq = 1193182 / (param & 0xffff); sysbeep(freq, period); } static void vtterm_cursor(struct terminal *tm, const term_pos_t *p) { struct vt_window *vw = tm->tm_softc; vtbuf_cursor_position(&vw->vw_buf, p); vt_resume_flush_timer(vw->vw_device, 0); } static void vtterm_putchar(struct terminal *tm, const term_pos_t *p, term_char_t c) { struct vt_window *vw = tm->tm_softc; vtbuf_putchar(&vw->vw_buf, p, c); vt_resume_flush_timer(vw->vw_device, 0); } static void vtterm_fill(struct terminal *tm, const term_rect_t *r, term_char_t c) { struct vt_window *vw = tm->tm_softc; vtbuf_fill_locked(&vw->vw_buf, r, c); vt_resume_flush_timer(vw->vw_device, 0); } static void vtterm_copy(struct terminal *tm, const term_rect_t *r, const term_pos_t *p) { struct vt_window *vw = tm->tm_softc; vtbuf_copy(&vw->vw_buf, r, p); vt_resume_flush_timer(vw->vw_device, 0); } static void vtterm_param(struct terminal *tm, int cmd, unsigned int arg) { struct vt_window *vw = tm->tm_softc; switch (cmd) { case TP_SHOWCURSOR: vtbuf_cursor_visibility(&vw->vw_buf, arg); vt_resume_flush_timer(vw->vw_device, 0); break; case TP_MOUSE: vw->vw_mouse_level = arg; break; } } void vt_determine_colors(term_char_t c, int cursor, term_color_t *fg, term_color_t *bg) { term_color_t tmp; int invert; invert = 0; *fg = TCHAR_FGCOLOR(c); if (TCHAR_FORMAT(c) & TF_BOLD) *fg = TCOLOR_LIGHT(*fg); *bg = TCHAR_BGCOLOR(c); if (TCHAR_FORMAT(c) & TF_REVERSE) invert ^= 1; if (cursor) invert ^= 1; if (invert) { tmp = *fg; *fg = *bg; *bg = tmp; } } #ifndef SC_NO_CUTPASTE int vt_is_cursor_in_area(const struct vt_device *vd, const term_rect_t *area) { unsigned int mx, my; /* * We use the cursor position saved during the current refresh, * in case the cursor moved since. */ mx = vd->vd_mx_drawn + vd->vd_curwindow->vw_draw_area.tr_begin.tp_col; my = vd->vd_my_drawn + vd->vd_curwindow->vw_draw_area.tr_begin.tp_row; if (mx >= area->tr_end.tp_col || mx + vd->vd_mcursor->width <= area->tr_begin.tp_col || my >= area->tr_end.tp_row || my + vd->vd_mcursor->height <= area->tr_begin.tp_row) return (0); return (1); } static void vt_mark_mouse_position_as_dirty(struct vt_device *vd) { term_rect_t area; struct vt_window *vw; struct vt_font *vf; int x, y; vw = vd->vd_curwindow; vf = vw->vw_font; x = vd->vd_mx_drawn; y = vd->vd_my_drawn; if (vf != NULL) { area.tr_begin.tp_col = x / vf->vf_width; area.tr_begin.tp_row = y / vf->vf_height; area.tr_end.tp_col = ((x + vd->vd_mcursor->width) / vf->vf_width) + 1; area.tr_end.tp_row = ((y + vd->vd_mcursor->height) / vf->vf_height) + 1; } else { /* * No font loaded (ie. vt_vga operating in textmode). * * FIXME: This fake area needs to be revisited once the * mouse cursor is supported in vt_vga's textmode. */ area.tr_begin.tp_col = x; area.tr_begin.tp_row = y; area.tr_end.tp_col = x + 2; area.tr_end.tp_row = y + 2; } vtbuf_dirty(&vw->vw_buf, &area); } #endif static int vt_flush(struct vt_device *vd) { struct vt_window *vw; struct vt_font *vf; term_rect_t tarea; #ifndef SC_NO_CUTPASTE int cursor_was_shown, cursor_moved; #endif vw = vd->vd_curwindow; if (vw == NULL) return (0); if (vd->vd_flags & VDF_SPLASH || vw->vw_flags & VWF_BUSY) return (0); vf = vw->vw_font; if (((vd->vd_flags & VDF_TEXTMODE) == 0) && (vf == NULL)) return (0); #ifndef SC_NO_CUTPASTE cursor_was_shown = vd->vd_mshown; cursor_moved = (vd->vd_mx != vd->vd_mx_drawn || vd->vd_my != vd->vd_my_drawn); /* Check if the cursor should be displayed or not. */ if ((vd->vd_flags & VDF_MOUSECURSOR) && /* Mouse support enabled. */ !(vw->vw_flags & VWF_MOUSE_HIDE) && /* Cursor displayed. */ !kdb_active && panicstr == NULL) { /* DDB inactive. */ vd->vd_mshown = 1; } else { vd->vd_mshown = 0; } /* * If the cursor changed display state or moved, we must mark * the old position as dirty, so that it's erased. */ if (cursor_was_shown != vd->vd_mshown || (vd->vd_mshown && cursor_moved)) vt_mark_mouse_position_as_dirty(vd); /* * Save position of the mouse cursor. It's used by backends to * know where to draw the cursor and during the next refresh to * erase the previous position. */ vd->vd_mx_drawn = vd->vd_mx; vd->vd_my_drawn = vd->vd_my; /* * If the cursor is displayed and has moved since last refresh, * mark the new position as dirty. */ if (vd->vd_mshown && cursor_moved) vt_mark_mouse_position_as_dirty(vd); #endif vtbuf_undirty(&vw->vw_buf, &tarea); /* Force a full redraw when the screen contents are invalid. */ if (vd->vd_flags & VDF_INVALID) { vd->vd_flags &= ~VDF_INVALID; vt_termrect(vd, vf, &tarea); if (vt_draw_logo_cpus) vtterm_draw_cpu_logos(vd); } if (tarea.tr_begin.tp_col < tarea.tr_end.tp_col) { vd->vd_driver->vd_bitblt_text(vd, vw, &tarea); return (1); } return (0); } static void vt_timer(void *arg) { struct vt_device *vd; int changed; vd = arg; /* Update screen if required. */ changed = vt_flush(vd); /* Schedule for next update. */ if (changed) vt_schedule_flush(vd, 0); else vd->vd_timer_armed = 0; } static void vtterm_done(struct terminal *tm) { struct vt_window *vw = tm->tm_softc; struct vt_device *vd = vw->vw_device; if (kdb_active || panicstr != NULL) { /* Switch to the debugger. */ if (vd->vd_curwindow != vw) { vd->vd_curwindow = vw; vd->vd_flags |= VDF_INVALID; if (vd->vd_driver->vd_postswitch) vd->vd_driver->vd_postswitch(vd); } vd->vd_flags &= ~VDF_SPLASH; vt_flush(vd); } else if (!(vd->vd_flags & VDF_ASYNC)) { vt_flush(vd); } } #ifdef DEV_SPLASH static void vtterm_splash(struct vt_device *vd) { vt_axis_t top, left; /* Display a nice boot splash. */ if (!(vd->vd_flags & VDF_TEXTMODE) && (boothowto & RB_MUTE)) { top = (vd->vd_height - vt_logo_height) / 2; left = (vd->vd_width - vt_logo_width) / 2; switch (vt_logo_depth) { case 1: /* XXX: Unhardcode colors! */ vd->vd_driver->vd_bitblt_bmp(vd, vd->vd_curwindow, vt_logo_image, NULL, vt_logo_width, vt_logo_height, left, top, TC_WHITE, TC_BLACK); } vd->vd_flags |= VDF_SPLASH; } } #endif static void vtterm_cnprobe(struct terminal *tm, struct consdev *cp) { struct vt_driver *vtd, **vtdlist, *vtdbest = NULL; struct vt_window *vw = tm->tm_softc; struct vt_device *vd = vw->vw_device; struct winsize wsz; term_attr_t attr; term_char_t c; if (!vty_enabled(VTY_VT)) return; if (vd->vd_flags & VDF_INITIALIZED) /* Initialization already done. */ return; SET_FOREACH(vtdlist, vt_drv_set) { vtd = *vtdlist; if (vtd->vd_probe == NULL) continue; if (vtd->vd_probe(vd) == CN_DEAD) continue; if ((vtdbest == NULL) || (vtd->vd_priority > vtdbest->vd_priority)) vtdbest = vtd; } if (vtdbest == NULL) { cp->cn_pri = CN_DEAD; vd->vd_flags |= VDF_DEAD; } else { vd->vd_driver = vtdbest; cp->cn_pri = vd->vd_driver->vd_init(vd); } /* Check if driver's vt_init return CN_DEAD. */ if (cp->cn_pri == CN_DEAD) { vd->vd_flags |= VDF_DEAD; } /* Initialize any early-boot keyboard drivers */ kbd_configure(KB_CONF_PROBE_ONLY); vd->vd_unit = atomic_fetchadd_int(&vt_unit, 1); vd->vd_windows[VT_CONSWINDOW] = vw; sprintf(cp->cn_name, "ttyv%r", VT_UNIT(vw)); /* Attach default font if not in TEXTMODE. */ if ((vd->vd_flags & VDF_TEXTMODE) == 0) { vw->vw_font = vtfont_ref(&vt_font_default); vt_compute_drawable_area(vw); } /* * The original screen size was faked (_VTDEFW x _VTDEFH). Now * that we have the real viewable size, fix it in the static * buffer. */ if (vd->vd_width != 0 && vd->vd_height != 0) vt_termsize(vd, vw->vw_font, &vw->vw_buf.vb_scr_size); vtbuf_init_early(&vw->vw_buf); vt_winsize(vd, vw->vw_font, &wsz); c = (boothowto & RB_MUTE) == 0 ? TERMINAL_KERN_ATTR : TERMINAL_NORM_ATTR; attr.ta_format = TCHAR_FORMAT(c); attr.ta_fgcolor = TCHAR_FGCOLOR(c); attr.ta_bgcolor = TCHAR_BGCOLOR(c); terminal_set_winsize_blank(tm, &wsz, 1, &attr); if (vtdbest != NULL) { #ifdef DEV_SPLASH if (!vt_splash_cpu) vtterm_splash(vd); #endif vd->vd_flags |= VDF_INITIALIZED; } } static int vtterm_cngetc(struct terminal *tm) { struct vt_window *vw = tm->tm_softc; struct vt_device *vd = vw->vw_device; keyboard_t *kbd; u_int c; if (vw->vw_kbdsq && *vw->vw_kbdsq) return (*vw->vw_kbdsq++); /* Make sure the splash screen is not there. */ if (vd->vd_flags & VDF_SPLASH) { /* Remove splash */ vd->vd_flags &= ~VDF_SPLASH; /* Mark screen as invalid to force update */ vd->vd_flags |= VDF_INVALID; vt_flush(vd); } /* Stripped down keyboard handler. */ kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd == NULL) return (-1); /* Force keyboard input mode to K_XLATE */ vw->vw_kbdmode = K_XLATE; vt_update_kbd_mode(vw, kbd); /* Switch the keyboard to polling to make it work here. */ kbdd_poll(kbd, TRUE); c = kbdd_read_char(kbd, 0); kbdd_poll(kbd, FALSE); if (c & RELKEY) return (-1); if (vw->vw_flags & VWF_SCROLL) { vt_scrollmode_kbdevent(vw, c, 1/* Console mode */); vt_flush(vd); return (-1); } /* Stripped down handling of vt_kbdevent(), without locking, etc. */ if (c & SPCLKEY) { switch (c) { case SPCLKEY | SLK: vt_save_kbd_state(vw, kbd); if (vw->vw_kbdstate & SLKED) { /* Turn scrolling on. */ vw->vw_flags |= VWF_SCROLL; VTBUF_SLCK_ENABLE(&vw->vw_buf); } else { /* Turn scrolling off. */ vt_scroll(vw, 0, VHS_END); vw->vw_flags &= ~VWF_SCROLL; VTBUF_SLCK_DISABLE(&vw->vw_buf); } break; /* XXX: KDB can handle history. */ case SPCLKEY | FKEY | F(50): /* Arrow up. */ vw->vw_kbdsq = "\x1b[A"; break; case SPCLKEY | FKEY | F(58): /* Arrow down. */ vw->vw_kbdsq = "\x1b[B"; break; case SPCLKEY | FKEY | F(55): /* Arrow right. */ vw->vw_kbdsq = "\x1b[C"; break; case SPCLKEY | FKEY | F(53): /* Arrow left. */ vw->vw_kbdsq = "\x1b[D"; break; } /* Force refresh to make scrollback work. */ vt_flush(vd); } else if (KEYFLAGS(c) == 0) { return (KEYCHAR(c)); } if (vw->vw_kbdsq && *vw->vw_kbdsq) return (*vw->vw_kbdsq++); return (-1); } static void vtterm_cngrab(struct terminal *tm) { struct vt_device *vd; struct vt_window *vw; keyboard_t *kbd; vw = tm->tm_softc; vd = vw->vw_device; if (!cold) vt_window_switch(vw); kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd == NULL) return; if (vw->vw_grabbed++ > 0) return; /* * Make sure the keyboard is accessible even when the kbd device * driver is disabled. */ kbdd_enable(kbd); /* We shall always use the keyboard in the XLATE mode here. */ vw->vw_prev_kbdmode = vw->vw_kbdmode; vw->vw_kbdmode = K_XLATE; vt_update_kbd_mode(vw, kbd); kbdd_poll(kbd, TRUE); } static void vtterm_cnungrab(struct terminal *tm) { struct vt_device *vd; struct vt_window *vw; keyboard_t *kbd; vw = tm->tm_softc; vd = vw->vw_device; kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd == NULL) return; if (--vw->vw_grabbed > 0) return; kbdd_poll(kbd, FALSE); vw->vw_kbdmode = vw->vw_prev_kbdmode; vt_update_kbd_mode(vw, kbd); kbdd_disable(kbd); } static void vtterm_opened(struct terminal *tm, int opened) { struct vt_window *vw = tm->tm_softc; struct vt_device *vd = vw->vw_device; VT_LOCK(vd); vd->vd_flags &= ~VDF_SPLASH; if (opened) vw->vw_flags |= VWF_OPENED; else { vw->vw_flags &= ~VWF_OPENED; /* TODO: finish ACQ/REL */ } VT_UNLOCK(vd); } static int vt_set_border(struct vt_window *vw, term_color_t c) { struct vt_device *vd = vw->vw_device; if (vd->vd_driver->vd_drawrect == NULL) return (ENOTSUP); /* Top bar. */ if (vw->vw_draw_area.tr_begin.tp_row > 0) vd->vd_driver->vd_drawrect(vd, 0, 0, vd->vd_width - 1, vw->vw_draw_area.tr_begin.tp_row - 1, 1, c); /* Left bar. */ if (vw->vw_draw_area.tr_begin.tp_col > 0) vd->vd_driver->vd_drawrect(vd, 0, 0, vw->vw_draw_area.tr_begin.tp_col - 1, vd->vd_height - 1, 1, c); /* Right bar. */ if (vw->vw_draw_area.tr_end.tp_col < vd->vd_width) vd->vd_driver->vd_drawrect(vd, vw->vw_draw_area.tr_end.tp_col - 1, 0, vd->vd_width - 1, vd->vd_height - 1, 1, c); /* Bottom bar. */ if (vw->vw_draw_area.tr_end.tp_row < vd->vd_height) vd->vd_driver->vd_drawrect(vd, 0, vw->vw_draw_area.tr_end.tp_row - 1, vd->vd_width - 1, vd->vd_height - 1, 1, c); return (0); } static int vt_change_font(struct vt_window *vw, struct vt_font *vf) { struct vt_device *vd = vw->vw_device; struct terminal *tm = vw->vw_terminal; term_pos_t size; struct winsize wsz; /* * Changing fonts. * * Changing fonts is a little tricky. We must prevent * simultaneous access to the device, so we must stop * the display timer and the terminal from accessing. * We need to switch fonts and grow our screen buffer. * * XXX: Right now the code uses terminal_mute() to * prevent data from reaching the console driver while * resizing the screen buffer. This isn't elegant... */ VT_LOCK(vd); if (vw->vw_flags & VWF_BUSY) { /* Another process is changing the font. */ VT_UNLOCK(vd); return (EBUSY); } vw->vw_flags |= VWF_BUSY; VT_UNLOCK(vd); vt_termsize(vd, vf, &size); vt_winsize(vd, vf, &wsz); /* Grow the screen buffer and terminal. */ terminal_mute(tm, 1); vtbuf_grow(&vw->vw_buf, &size, vw->vw_buf.vb_history_size); terminal_set_winsize_blank(tm, &wsz, 0, NULL); terminal_set_cursor(tm, &vw->vw_buf.vb_cursor); terminal_mute(tm, 0); /* Actually apply the font to the current window. */ VT_LOCK(vd); if (vw->vw_font != vf && vw->vw_font != NULL && vf != NULL) { /* * In case vt_change_font called to update size we don't need * to update font link. */ vtfont_unref(vw->vw_font); vw->vw_font = vtfont_ref(vf); } /* * Compute the drawable area and move the mouse cursor inside * it, in case the new area is smaller than the previous one. */ vt_compute_drawable_area(vw); vd->vd_mx = min(vd->vd_mx, vw->vw_draw_area.tr_end.tp_col - vw->vw_draw_area.tr_begin.tp_col - 1); vd->vd_my = min(vd->vd_my, vw->vw_draw_area.tr_end.tp_row - vw->vw_draw_area.tr_begin.tp_row - 1); /* Force a full redraw the next timer tick. */ if (vd->vd_curwindow == vw) { vt_set_border(vw, TC_BLACK); vd->vd_flags |= VDF_INVALID; vt_resume_flush_timer(vw->vw_device, 0); } vw->vw_flags &= ~VWF_BUSY; VT_UNLOCK(vd); return (0); } static int vt_proc_alive(struct vt_window *vw) { struct proc *p; if (vw->vw_smode.mode != VT_PROCESS) return (FALSE); if (vw->vw_proc) { if ((p = pfind(vw->vw_pid)) != NULL) PROC_UNLOCK(p); if (vw->vw_proc == p) return (TRUE); vw->vw_proc = NULL; vw->vw_smode.mode = VT_AUTO; DPRINTF(1, "vt controlling process %d died\n", vw->vw_pid); vw->vw_pid = 0; } return (FALSE); } static int signal_vt_rel(struct vt_window *vw) { if (vw->vw_smode.mode != VT_PROCESS) return (FALSE); if (vw->vw_proc == NULL || vt_proc_alive(vw) == FALSE) { vw->vw_proc = NULL; vw->vw_pid = 0; return (TRUE); } vw->vw_flags |= VWF_SWWAIT_REL; PROC_LOCK(vw->vw_proc); kern_psignal(vw->vw_proc, vw->vw_smode.relsig); PROC_UNLOCK(vw->vw_proc); DPRINTF(1, "sending relsig to %d\n", vw->vw_pid); return (TRUE); } static int signal_vt_acq(struct vt_window *vw) { if (vw->vw_smode.mode != VT_PROCESS) return (FALSE); if (vw == vw->vw_device->vd_windows[VT_CONSWINDOW]) cnavailable(vw->vw_terminal->consdev, FALSE); if (vw->vw_proc == NULL || vt_proc_alive(vw) == FALSE) { vw->vw_proc = NULL; vw->vw_pid = 0; return (TRUE); } vw->vw_flags |= VWF_SWWAIT_ACQ; PROC_LOCK(vw->vw_proc); kern_psignal(vw->vw_proc, vw->vw_smode.acqsig); PROC_UNLOCK(vw->vw_proc); DPRINTF(1, "sending acqsig to %d\n", vw->vw_pid); return (TRUE); } static int finish_vt_rel(struct vt_window *vw, int release, int *s) { if (vw->vw_flags & VWF_SWWAIT_REL) { vw->vw_flags &= ~VWF_SWWAIT_REL; if (release) { callout_drain(&vw->vw_proc_dead_timer); vt_late_window_switch(vw->vw_switch_to); } return (0); } return (EINVAL); } static int finish_vt_acq(struct vt_window *vw) { if (vw->vw_flags & VWF_SWWAIT_ACQ) { vw->vw_flags &= ~VWF_SWWAIT_ACQ; return (0); } return (EINVAL); } #ifndef SC_NO_CUTPASTE static void vt_mouse_terminput_button(struct vt_device *vd, int button) { struct vt_window *vw; struct vt_font *vf; char mouseb[6] = "\x1B[M"; int i, x, y; vw = vd->vd_curwindow; vf = vw->vw_font; /* Translate to char position. */ x = vd->vd_mx / vf->vf_width; y = vd->vd_my / vf->vf_height; /* Avoid overflow. */ x = MIN(x, 255 - '!'); y = MIN(y, 255 - '!'); mouseb[3] = ' ' + button; mouseb[4] = '!' + x; mouseb[5] = '!' + y; for (i = 0; i < sizeof(mouseb); i++) terminal_input_char(vw->vw_terminal, mouseb[i]); } static void vt_mouse_terminput(struct vt_device *vd, int type, int x, int y, int event, int cnt) { switch (type) { case MOUSE_BUTTON_EVENT: if (cnt > 0) { /* Mouse button pressed. */ if (event & MOUSE_BUTTON1DOWN) vt_mouse_terminput_button(vd, 0); if (event & MOUSE_BUTTON2DOWN) vt_mouse_terminput_button(vd, 1); if (event & MOUSE_BUTTON3DOWN) vt_mouse_terminput_button(vd, 2); } else { /* Mouse button released. */ vt_mouse_terminput_button(vd, 3); } break; #ifdef notyet case MOUSE_MOTION_EVENT: if (mouse->u.data.z < 0) { /* Scroll up. */ sc_mouse_input_button(vd, 64); } else if (mouse->u.data.z > 0) { /* Scroll down. */ sc_mouse_input_button(vd, 65); } break; #endif } } static void vt_mouse_paste() { term_char_t *buf; int i, len; len = VD_PASTEBUFLEN(main_vd); buf = VD_PASTEBUF(main_vd); len /= sizeof(term_char_t); for (i = 0; i < len; i++) { if (buf[i] == '\0') continue; terminal_input_char(main_vd->vd_curwindow->vw_terminal, buf[i]); } } void vt_mouse_event(int type, int x, int y, int event, int cnt, int mlevel) { struct vt_device *vd; struct vt_window *vw; struct vt_font *vf; term_pos_t size; int len, mark; vd = main_vd; vw = vd->vd_curwindow; vf = vw->vw_font; mark = 0; if (vw->vw_flags & (VWF_MOUSE_HIDE | VWF_GRAPHICS)) /* * Either the mouse is disabled, or the window is in * "graphics mode". The graphics mode is usually set by * an X server, using the KDSETMODE ioctl. */ return; if (vf == NULL) /* Text mode. */ return; /* * TODO: add flag about pointer position changed, to not redraw chars * under mouse pointer when nothing changed. */ if (vw->vw_mouse_level > 0) vt_mouse_terminput(vd, type, x, y, event, cnt); switch (type) { case MOUSE_ACTION: case MOUSE_MOTION_EVENT: /* Movement */ x += vd->vd_mx; y += vd->vd_my; vt_termsize(vd, vf, &size); /* Apply limits. */ x = MAX(x, 0); y = MAX(y, 0); x = MIN(x, (size.tp_col * vf->vf_width) - 1); y = MIN(y, (size.tp_row * vf->vf_height) - 1); vd->vd_mx = x; vd->vd_my = y; if (vd->vd_mstate & MOUSE_BUTTON1DOWN) vtbuf_set_mark(&vw->vw_buf, VTB_MARK_MOVE, vd->vd_mx / vf->vf_width, vd->vd_my / vf->vf_height); vt_resume_flush_timer(vw->vw_device, 0); return; /* Done */ case MOUSE_BUTTON_EVENT: /* Buttons */ break; default: return; /* Done */ } switch (event) { case MOUSE_BUTTON1DOWN: switch (cnt % 4) { case 0: /* up */ mark = VTB_MARK_END; break; case 1: /* single click: start cut operation */ mark = VTB_MARK_START; break; case 2: /* double click: cut a word */ mark = VTB_MARK_WORD; break; case 3: /* triple click: cut a line */ mark = VTB_MARK_ROW; break; } break; case VT_MOUSE_PASTEBUTTON: switch (cnt) { case 0: /* up */ break; default: vt_mouse_paste(); break; } return; /* Done */ case VT_MOUSE_EXTENDBUTTON: switch (cnt) { case 0: /* up */ if (!(vd->vd_mstate & MOUSE_BUTTON1DOWN)) mark = VTB_MARK_EXTEND; else mark = 0; break; default: mark = VTB_MARK_EXTEND; break; } break; default: return; /* Done */ } /* Save buttons state. */ if (cnt > 0) vd->vd_mstate |= event; else vd->vd_mstate &= ~event; if (vtbuf_set_mark(&vw->vw_buf, mark, vd->vd_mx / vf->vf_width, vd->vd_my / vf->vf_height) == 1) { /* * We have something marked to copy, so update pointer to * window with selection. */ vt_resume_flush_timer(vw->vw_device, 0); switch (mark) { case VTB_MARK_END: case VTB_MARK_WORD: case VTB_MARK_ROW: case VTB_MARK_EXTEND: break; default: /* Other types of mark do not require to copy data. */ return; } /* Get current selection size in bytes. */ len = vtbuf_get_marked_len(&vw->vw_buf); if (len <= 0) return; /* Reallocate buffer only if old one is too small. */ if (len > VD_PASTEBUFSZ(vd)) { VD_PASTEBUF(vd) = realloc(VD_PASTEBUF(vd), len, M_VT, M_WAITOK | M_ZERO); /* Update buffer size. */ VD_PASTEBUFSZ(vd) = len; } /* Request copy/paste buffer data, no more than `len' */ vtbuf_extract_marked(&vw->vw_buf, VD_PASTEBUF(vd), VD_PASTEBUFSZ(vd)); VD_PASTEBUFLEN(vd) = len; /* XXX VD_PASTEBUF(vd) have to be freed on shutdown/unload. */ } } void vt_mouse_state(int show) { struct vt_device *vd; struct vt_window *vw; vd = main_vd; vw = vd->vd_curwindow; switch (show) { case VT_MOUSE_HIDE: vw->vw_flags |= VWF_MOUSE_HIDE; break; case VT_MOUSE_SHOW: vw->vw_flags &= ~VWF_MOUSE_HIDE; break; } /* Mark mouse position as dirty. */ vt_mark_mouse_position_as_dirty(vd); vt_resume_flush_timer(vw->vw_device, 0); } #endif static int vtterm_mmap(struct terminal *tm, vm_ooffset_t offset, vm_paddr_t * paddr, int nprot, vm_memattr_t *memattr) { struct vt_window *vw = tm->tm_softc; struct vt_device *vd = vw->vw_device; if (vd->vd_driver->vd_fb_mmap) return (vd->vd_driver->vd_fb_mmap(vd, offset, paddr, nprot, memattr)); return (ENXIO); } static int vtterm_ioctl(struct terminal *tm, u_long cmd, caddr_t data, struct thread *td) { struct vt_window *vw = tm->tm_softc; struct vt_device *vd = vw->vw_device; keyboard_t *kbd; int error, i, s; #if defined(COMPAT_FREEBSD6) || defined(COMPAT_FREEBSD5) || \ defined(COMPAT_FREEBSD4) || defined(COMPAT_43) int ival; switch (cmd) { case _IO('v', 4): cmd = VT_RELDISP; break; case _IO('v', 5): cmd = VT_ACTIVATE; break; case _IO('v', 6): cmd = VT_WAITACTIVE; break; case _IO('K', 20): cmd = KDSKBSTATE; break; case _IO('K', 67): cmd = KDSETRAD; break; case _IO('K', 7): cmd = KDSKBMODE; break; case _IO('K', 8): cmd = KDMKTONE; break; case _IO('K', 63): cmd = KIOCSOUND; break; case _IO('K', 66): cmd = KDSETLED; break; case _IO('c', 110): cmd = CONS_SETKBD; break; default: goto skip_thunk; } ival = IOCPARM_IVAL(data); data = (caddr_t)&ival; skip_thunk: #endif switch (cmd) { case KDSETRAD: /* set keyboard repeat & delay rates (old) */ if (*(int *)data & ~0x7f) return (EINVAL); /* FALLTHROUGH */ case GIO_KEYMAP: case PIO_KEYMAP: case GIO_DEADKEYMAP: case PIO_DEADKEYMAP: case GETFKEY: case SETFKEY: case KDGKBINFO: case KDGKBTYPE: case KDGETREPEAT: /* get keyboard repeat & delay rates */ case KDSETREPEAT: /* set keyboard repeat & delay rates (new) */ case KBADDKBD: /* add/remove keyboard to/from mux */ case KBRELKBD: { error = 0; mtx_lock(&Giant); kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd != NULL) error = kbdd_ioctl(kbd, cmd, data); mtx_unlock(&Giant); if (error == ENOIOCTL) { if (cmd == KDGKBTYPE) { /* always return something? XXX */ *(int *)data = 0; } else { return (ENODEV); } } return (error); } case KDGKBSTATE: { /* get keyboard state (locks) */ error = 0; if (vw == vd->vd_curwindow) { mtx_lock(&Giant); kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd != NULL) error = vt_save_kbd_state(vw, kbd); mtx_unlock(&Giant); if (error != 0) return (error); } *(int *)data = vw->vw_kbdstate & LOCK_MASK; return (error); } case KDSKBSTATE: { /* set keyboard state (locks) */ int state; state = *(int *)data; if (state & ~LOCK_MASK) return (EINVAL); vw->vw_kbdstate &= ~LOCK_MASK; vw->vw_kbdstate |= state; error = 0; if (vw == vd->vd_curwindow) { mtx_lock(&Giant); kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd != NULL) error = vt_update_kbd_state(vw, kbd); mtx_unlock(&Giant); } return (error); } case KDGETLED: { /* get keyboard LED status */ error = 0; if (vw == vd->vd_curwindow) { mtx_lock(&Giant); kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd != NULL) error = vt_save_kbd_leds(vw, kbd); mtx_unlock(&Giant); if (error != 0) return (error); } *(int *)data = vw->vw_kbdstate & LED_MASK; return (error); } case KDSETLED: { /* set keyboard LED status */ int leds; leds = *(int *)data; if (leds & ~LED_MASK) return (EINVAL); vw->vw_kbdstate &= ~LED_MASK; vw->vw_kbdstate |= leds; error = 0; if (vw == vd->vd_curwindow) { mtx_lock(&Giant); kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd != NULL) error = vt_update_kbd_leds(vw, kbd); mtx_unlock(&Giant); } return (error); } case KDGKBMODE: { error = 0; if (vw == vd->vd_curwindow) { mtx_lock(&Giant); kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd != NULL) error = vt_save_kbd_mode(vw, kbd); mtx_unlock(&Giant); if (error != 0) return (error); } *(int *)data = vw->vw_kbdmode; return (error); } case KDSKBMODE: { int mode; mode = *(int *)data; switch (mode) { case K_XLATE: case K_RAW: case K_CODE: vw->vw_kbdmode = mode; error = 0; if (vw == vd->vd_curwindow) { mtx_lock(&Giant); kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd != NULL) error = vt_update_kbd_mode(vw, kbd); mtx_unlock(&Giant); } return (error); default: return (EINVAL); } } case FBIOGTYPE: case FBIO_GETWINORG: /* get frame buffer window origin */ case FBIO_GETDISPSTART: /* get display start address */ case FBIO_GETLINEWIDTH: /* get scan line width in bytes */ case FBIO_BLANK: /* blank display */ if (vd->vd_driver->vd_fb_ioctl) return (vd->vd_driver->vd_fb_ioctl(vd, cmd, data, td)); break; case CONS_BLANKTIME: /* XXX */ return (0); case CONS_GET: /* XXX */ *(int *)data = M_CG640x480; return (0); case CONS_BELLTYPE: /* set bell type sound */ if ((*(int *)data) & CONS_QUIET_BELL) vd->vd_flags |= VDF_QUIET_BELL; else vd->vd_flags &= ~VDF_QUIET_BELL; return (0); case CONS_GETINFO: { vid_info_t *vi = (vid_info_t *)data; if (vi->size != sizeof(struct vid_info)) return (EINVAL); if (vw == vd->vd_curwindow) { kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd != NULL) vt_save_kbd_state(vw, kbd); } vi->m_num = vd->vd_curwindow->vw_number + 1; vi->mk_keylock = vw->vw_kbdstate & LOCK_MASK; /* XXX: other fields! */ return (0); } case CONS_GETVERS: *(int *)data = 0x200; return (0); case CONS_MODEINFO: /* XXX */ return (0); case CONS_MOUSECTL: { mouse_info_t *mouse = (mouse_info_t*)data; /* * All the commands except MOUSE_SHOW nd MOUSE_HIDE * should not be applied to individual TTYs, but only to * consolectl. */ switch (mouse->operation) { case MOUSE_HIDE: if (vd->vd_flags & VDF_MOUSECURSOR) { vd->vd_flags &= ~VDF_MOUSECURSOR; #ifndef SC_NO_CUTPASTE vt_mouse_state(VT_MOUSE_HIDE); #endif } return (0); case MOUSE_SHOW: if (!(vd->vd_flags & VDF_MOUSECURSOR)) { vd->vd_flags |= VDF_MOUSECURSOR; vd->vd_mx = vd->vd_width / 2; vd->vd_my = vd->vd_height / 2; #ifndef SC_NO_CUTPASTE vt_mouse_state(VT_MOUSE_SHOW); #endif } return (0); default: return (EINVAL); } } case PIO_VFONT: { struct vt_font *vf; if (vd->vd_flags & VDF_TEXTMODE) return (ENOTSUP); error = vtfont_load((void *)data, &vf); if (error != 0) return (error); error = vt_change_font(vw, vf); vtfont_unref(vf); return (error); } case PIO_VFONT_DEFAULT: { /* Reset to default font. */ error = vt_change_font(vw, &vt_font_default); return (error); } case GIO_SCRNMAP: { scrmap_t *sm = (scrmap_t *)data; /* We don't have screen maps, so return a handcrafted one. */ for (i = 0; i < 256; i++) sm->scrmap[i] = i; return (0); } case KDSETMODE: /* * FIXME: This implementation is incomplete compared to * syscons. */ switch (*(int *)data) { case KD_TEXT: case KD_TEXT1: case KD_PIXEL: vw->vw_flags &= ~VWF_GRAPHICS; break; case KD_GRAPHICS: vw->vw_flags |= VWF_GRAPHICS; break; } return (0); case KDENABIO: /* allow io operations */ error = priv_check(td, PRIV_IO); if (error != 0) return (error); error = securelevel_gt(td->td_ucred, 0); if (error != 0) return (error); #if defined(__i386__) td->td_frame->tf_eflags |= PSL_IOPL; #elif defined(__amd64__) td->td_frame->tf_rflags |= PSL_IOPL; #endif return (0); case KDDISABIO: /* disallow io operations (default) */ #if defined(__i386__) td->td_frame->tf_eflags &= ~PSL_IOPL; #elif defined(__amd64__) td->td_frame->tf_rflags &= ~PSL_IOPL; #endif return (0); case KDMKTONE: /* sound the bell */ vtterm_beep(tm, *(u_int *)data); return (0); case KIOCSOUND: /* make tone (*data) hz */ /* TODO */ return (0); case CONS_SETKBD: /* set the new keyboard */ mtx_lock(&Giant); error = 0; if (vd->vd_keyboard != *(int *)data) { kbd = kbd_get_keyboard(*(int *)data); if (kbd == NULL) { mtx_unlock(&Giant); return (EINVAL); } i = kbd_allocate(kbd->kb_name, kbd->kb_unit, (void *)vd, vt_kbdevent, vd); if (i >= 0) { if (vd->vd_keyboard != -1) { vt_save_kbd_state(vd->vd_curwindow, kbd); kbd_release(kbd, (void *)vd); } kbd = kbd_get_keyboard(i); vd->vd_keyboard = i; vt_update_kbd_mode(vd->vd_curwindow, kbd); vt_update_kbd_state(vd->vd_curwindow, kbd); } else { error = EPERM; /* XXX */ } } mtx_unlock(&Giant); return (error); case CONS_RELKBD: /* release the current keyboard */ mtx_lock(&Giant); error = 0; if (vd->vd_keyboard != -1) { kbd = kbd_get_keyboard(vd->vd_keyboard); if (kbd == NULL) { mtx_unlock(&Giant); return (EINVAL); } vt_save_kbd_state(vd->vd_curwindow, kbd); error = kbd_release(kbd, (void *)vd); if (error == 0) { vd->vd_keyboard = -1; } } mtx_unlock(&Giant); return (error); case VT_ACTIVATE: { int win; win = *(int *)data - 1; DPRINTF(5, "%s%d: VT_ACTIVATE ttyv%d ", SC_DRIVER_NAME, VT_UNIT(vw), win); if ((win >= VT_MAXWINDOWS) || (win < 0)) return (EINVAL); return (vt_proc_window_switch(vd->vd_windows[win])); } case VT_GETACTIVE: *(int *)data = vd->vd_curwindow->vw_number + 1; return (0); case VT_GETINDEX: *(int *)data = vw->vw_number + 1; return (0); case VT_LOCKSWITCH: /* TODO: Check current state, switching can be in progress. */ if ((*(int *)data) == 0x01) vw->vw_flags |= VWF_VTYLOCK; else if ((*(int *)data) == 0x02) vw->vw_flags &= ~VWF_VTYLOCK; else return (EINVAL); return (0); case VT_OPENQRY: VT_LOCK(vd); for (i = 0; i < VT_MAXWINDOWS; i++) { vw = vd->vd_windows[i]; if (vw == NULL) continue; if (!(vw->vw_flags & VWF_OPENED)) { *(int *)data = vw->vw_number + 1; VT_UNLOCK(vd); return (0); } } VT_UNLOCK(vd); return (EINVAL); case VT_WAITACTIVE: { unsigned int idx; error = 0; idx = *(unsigned int *)data; if (idx > VT_MAXWINDOWS) return (EINVAL); if (idx > 0) vw = vd->vd_windows[idx - 1]; VT_LOCK(vd); while (vd->vd_curwindow != vw && error == 0) error = cv_wait_sig(&vd->vd_winswitch, &vd->vd_lock); VT_UNLOCK(vd); return (error); } case VT_SETMODE: { /* set screen switcher mode */ struct vt_mode *mode; struct proc *p1; mode = (struct vt_mode *)data; DPRINTF(5, "%s%d: VT_SETMODE ", SC_DRIVER_NAME, VT_UNIT(vw)); if (vw->vw_smode.mode == VT_PROCESS) { p1 = pfind(vw->vw_pid); if (vw->vw_proc == p1 && vw->vw_proc != td->td_proc) { if (p1) PROC_UNLOCK(p1); DPRINTF(5, "error EPERM\n"); return (EPERM); } if (p1) PROC_UNLOCK(p1); } if (mode->mode == VT_AUTO) { vw->vw_smode.mode = VT_AUTO; vw->vw_proc = NULL; vw->vw_pid = 0; DPRINTF(5, "VT_AUTO, "); if (vw == vw->vw_device->vd_windows[VT_CONSWINDOW]) cnavailable(vw->vw_terminal->consdev, TRUE); /* were we in the middle of the vty switching process? */ if (finish_vt_rel(vw, TRUE, &s) == 0) DPRINTF(5, "reset WAIT_REL, "); if (finish_vt_acq(vw) == 0) DPRINTF(5, "reset WAIT_ACQ, "); return (0); } else if (mode->mode == VT_PROCESS) { if (!ISSIGVALID(mode->relsig) || !ISSIGVALID(mode->acqsig) || !ISSIGVALID(mode->frsig)) { DPRINTF(5, "error EINVAL\n"); return (EINVAL); } DPRINTF(5, "VT_PROCESS %d, ", td->td_proc->p_pid); bcopy(data, &vw->vw_smode, sizeof(struct vt_mode)); vw->vw_proc = td->td_proc; vw->vw_pid = vw->vw_proc->p_pid; if (vw == vw->vw_device->vd_windows[VT_CONSWINDOW]) cnavailable(vw->vw_terminal->consdev, FALSE); } else { DPRINTF(5, "VT_SETMODE failed, unknown mode %d\n", mode->mode); return (EINVAL); } DPRINTF(5, "\n"); return (0); } case VT_GETMODE: /* get screen switcher mode */ bcopy(&vw->vw_smode, data, sizeof(struct vt_mode)); return (0); case VT_RELDISP: /* screen switcher ioctl */ /* * This must be the current vty which is in the VT_PROCESS * switching mode... */ if ((vw != vd->vd_curwindow) || (vw->vw_smode.mode != VT_PROCESS)) { return (EINVAL); } /* ...and this process is controlling it. */ if (vw->vw_proc != td->td_proc) { return (EPERM); } error = EINVAL; switch(*(int *)data) { case VT_FALSE: /* user refuses to release screen, abort */ if ((error = finish_vt_rel(vw, FALSE, &s)) == 0) DPRINTF(5, "%s%d: VT_RELDISP: VT_FALSE\n", SC_DRIVER_NAME, VT_UNIT(vw)); break; case VT_TRUE: /* user has released screen, go on */ /* finish_vt_rel(..., TRUE, ...) should not be locked */ if (vw->vw_flags & VWF_SWWAIT_REL) { if ((error = finish_vt_rel(vw, TRUE, &s)) == 0) DPRINTF(5, "%s%d: VT_RELDISP: VT_TRUE\n", SC_DRIVER_NAME, VT_UNIT(vw)); } else { error = EINVAL; } return (error); case VT_ACKACQ: /* acquire acknowledged, switch completed */ if ((error = finish_vt_acq(vw)) == 0) DPRINTF(5, "%s%d: VT_RELDISP: VT_ACKACQ\n", SC_DRIVER_NAME, VT_UNIT(vw)); break; default: break; } return (error); } return (ENOIOCTL); } static struct vt_window * vt_allocate_window(struct vt_device *vd, unsigned int window) { struct vt_window *vw; struct terminal *tm; term_pos_t size; struct winsize wsz; vw = malloc(sizeof *vw, M_VT, M_WAITOK|M_ZERO); vw->vw_device = vd; vw->vw_number = window; vw->vw_kbdmode = K_XLATE; if ((vd->vd_flags & VDF_TEXTMODE) == 0) { vw->vw_font = vtfont_ref(&vt_font_default); vt_compute_drawable_area(vw); } vt_termsize(vd, vw->vw_font, &size); vt_winsize(vd, vw->vw_font, &wsz); vtbuf_init(&vw->vw_buf, &size); tm = vw->vw_terminal = terminal_alloc(&vt_termclass, vw); terminal_set_winsize(tm, &wsz); vd->vd_windows[window] = vw; callout_init(&vw->vw_proc_dead_timer, 0); return (vw); } void vt_upgrade(struct vt_device *vd) { struct vt_window *vw; unsigned int i; int register_handlers; if (!vty_enabled(VTY_VT)) return; if (main_vd->vd_driver == NULL) return; for (i = 0; i < VT_MAXWINDOWS; i++) { vw = vd->vd_windows[i]; if (vw == NULL) { /* New window. */ vw = vt_allocate_window(vd, i); } if (!(vw->vw_flags & VWF_READY)) { callout_init(&vw->vw_proc_dead_timer, 0); terminal_maketty(vw->vw_terminal, "v%r", VT_UNIT(vw)); vw->vw_flags |= VWF_READY; if (vw->vw_flags & VWF_CONSOLE) { /* For existing console window. */ EVENTHANDLER_REGISTER(shutdown_pre_sync, vt_window_switch, vw, SHUTDOWN_PRI_DEFAULT); } } } VT_LOCK(vd); if (vd->vd_curwindow == NULL) vd->vd_curwindow = vd->vd_windows[VT_CONSWINDOW]; register_handlers = 0; if (!(vd->vd_flags & VDF_ASYNC)) { /* Attach keyboard. */ vt_allocate_keyboard(vd); /* Init 25 Hz timer. */ callout_init_mtx(&vd->vd_timer, &vd->vd_lock, 0); /* Start timer when everything ready. */ vd->vd_flags |= VDF_ASYNC; callout_reset(&vd->vd_timer, hz / VT_TIMERFREQ, vt_timer, vd); vd->vd_timer_armed = 1; register_handlers = 1; } VT_UNLOCK(vd); /* Refill settings with new sizes. */ vt_resize(vd); if (register_handlers) { /* Register suspend/resume handlers. */ EVENTHANDLER_REGISTER(power_suspend_early, vt_suspend_handler, vd, EVENTHANDLER_PRI_ANY); EVENTHANDLER_REGISTER(power_resume, vt_resume_handler, vd, EVENTHANDLER_PRI_ANY); } } static void vt_resize(struct vt_device *vd) { struct vt_window *vw; int i; for (i = 0; i < VT_MAXWINDOWS; i++) { vw = vd->vd_windows[i]; VT_LOCK(vd); /* Assign default font to window, if not textmode. */ if (!(vd->vd_flags & VDF_TEXTMODE) && vw->vw_font == NULL) vw->vw_font = vtfont_ref(&vt_font_default); VT_UNLOCK(vd); /* Resize terminal windows */ while (vt_change_font(vw, vw->vw_font) == EBUSY) { DPRINTF(100, "%s: vt_change_font() is busy, " "window %d\n", __func__, i); } } } static void vt_replace_backend(const struct vt_driver *drv, void *softc) { struct vt_device *vd; vd = main_vd; if (vd->vd_flags & VDF_ASYNC) { /* Stop vt_flush periodic task. */ VT_LOCK(vd); vt_suspend_flush_timer(vd); VT_UNLOCK(vd); /* * Mute current terminal until we done. vt_change_font (called * from vt_resize) will unmute it. */ terminal_mute(vd->vd_curwindow->vw_terminal, 1); } /* * Reset VDF_TEXTMODE flag, driver who require that flag (vt_vga) will * set it. */ VT_LOCK(vd); vd->vd_flags &= ~VDF_TEXTMODE; if (drv != NULL) { /* * We want to upgrade from the current driver to the * given driver. */ vd->vd_prev_driver = vd->vd_driver; vd->vd_prev_softc = vd->vd_softc; vd->vd_driver = drv; vd->vd_softc = softc; vd->vd_driver->vd_init(vd); } else if (vd->vd_prev_driver != NULL && vd->vd_prev_softc != NULL) { /* * No driver given: we want to downgrade to the previous * driver. */ const struct vt_driver *old_drv; void *old_softc; old_drv = vd->vd_driver; old_softc = vd->vd_softc; vd->vd_driver = vd->vd_prev_driver; vd->vd_softc = vd->vd_prev_softc; vd->vd_prev_driver = NULL; vd->vd_prev_softc = NULL; vd->vd_flags |= VDF_DOWNGRADE; vd->vd_driver->vd_init(vd); if (old_drv->vd_fini) old_drv->vd_fini(vd, old_softc); vd->vd_flags &= ~VDF_DOWNGRADE; } VT_UNLOCK(vd); /* Update windows sizes and initialize last items. */ vt_upgrade(vd); #ifdef DEV_SPLASH if (vd->vd_flags & VDF_SPLASH) vtterm_splash(vd); #endif if (vd->vd_flags & VDF_ASYNC) { /* Allow to put chars now. */ terminal_mute(vd->vd_curwindow->vw_terminal, 0); /* Rerun timer for screen updates. */ vt_resume_flush_timer(vd, 0); } /* * Register as console. If it already registered, cnadd() will ignore * it. */ termcn_cnregister(vd->vd_windows[VT_CONSWINDOW]->vw_terminal); } static void vt_suspend_handler(void *priv) { struct vt_device *vd; vd = priv; if (vd->vd_driver != NULL && vd->vd_driver->vd_suspend != NULL) vd->vd_driver->vd_suspend(vd); } static void vt_resume_handler(void *priv) { struct vt_device *vd; vd = priv; if (vd->vd_driver != NULL && vd->vd_driver->vd_resume != NULL) vd->vd_driver->vd_resume(vd); } void vt_allocate(const struct vt_driver *drv, void *softc) { if (!vty_enabled(VTY_VT)) return; if (main_vd->vd_driver == NULL) { main_vd->vd_driver = drv; printf("VT: initialize with new VT driver \"%s\".\n", drv->vd_name); } else { /* * Check if have rights to replace current driver. For example: * it is bad idea to replace KMS driver with generic VGA one. */ if (drv->vd_priority <= main_vd->vd_driver->vd_priority) { printf("VT: Driver priority %d too low. Current %d\n ", drv->vd_priority, main_vd->vd_driver->vd_priority); return; } printf("VT: Replacing driver \"%s\" with new \"%s\".\n", main_vd->vd_driver->vd_name, drv->vd_name); } vt_replace_backend(drv, softc); } void vt_deallocate(const struct vt_driver *drv, void *softc) { if (!vty_enabled(VTY_VT)) return; if (main_vd->vd_prev_driver == NULL || main_vd->vd_driver != drv || main_vd->vd_softc != softc) return; printf("VT: Switching back from \"%s\" to \"%s\".\n", main_vd->vd_driver->vd_name, main_vd->vd_prev_driver->vd_name); vt_replace_backend(NULL, NULL); } void vt_suspend(struct vt_device *vd) { int error; if (vt_suspendswitch == 0) return; /* Save current window. */ vd->vd_savedwindow = vd->vd_curwindow; /* Ask holding process to free window and switch to console window */ vt_proc_window_switch(vd->vd_windows[VT_CONSWINDOW]); /* Wait for the window switch to complete. */ error = 0; VT_LOCK(vd); while (vd->vd_curwindow != vd->vd_windows[VT_CONSWINDOW] && error == 0) error = cv_wait_sig(&vd->vd_winswitch, &vd->vd_lock); VT_UNLOCK(vd); } void vt_resume(struct vt_device *vd) { if (vt_suspendswitch == 0) return; /* Switch back to saved window, if any */ vt_proc_window_switch(vd->vd_savedwindow); vd->vd_savedwindow = NULL; }